Print wiring board

ABSTRACT

To cancel a magnetic field in an interconnection pattern of a printed wiring board.  
     A first interconnection pattern  3   a  is formed on a surface 1 a  of an insulating substrate 1. A second interconnection pattern  5   a  is formed on a bottom surface  1   b  of the insulating substrate  1  so as to be superposed on a meandering part of the first interconnection pattern  3   a  when viewed from the upper surface side. An end part  5   b  of the second interconnection pattern  5   a  is electrically connected to an end part  3   d  of the first interconnection pattern  3   a  via through holes  7   a.  The first interconnection pattern  3   a  and the second interconnection pattern  5   a  form a single interconnection line via the through holes  7   a.  Accordingly, the first interconnection pattern  3   a  and the second interconnection pattern  5   a  are 180° different from each other in the direction in which current flows. the second interconnection pattern are sandwiched between insulating materials so that no metal plating is provided on the first interconnection pattern and the second interconnection pattern.  
     The printed wiring board as claimed in any of claims  6  to  9,  wherein the first interconnection pattern and the second interconnection pattern are formed meanderingly.

TECHNICAL FIELD

The present invention relates to printed wiring boards.

BACKGROUND ART

Conventionally, there are a method of getting the original circuit performance out of a high-frequency semiconductor circuit chip by reducing inductance in interconnection lines and a method of suppressing noise emitted from a cable connected to a printed wiring board.

For instance, there is a method of getting the original performance out of a high-frequency semiconductor circuit chip by reducing mutual inductance by disposing a ground line and a signal line corresponding thereto closely so that they are side by side in positions such that the magnetic fields created by the ground line and the signal line cancel each other, considering a disposition including the signal line, in the case of mounting a high-frequency semiconductor circuit chip formed of gallium arsenide (GaAs) or the like in a package and electrically connecting it to a printed wiring board or the like by wire bonding (for instance, see Patent Document 1).

There is disclosure of a method of suppressing noise emitted from a cable by causing current flowing through the cable to have magnetic fields generated around the cable cancel each other by having the cable, connected to a printed wiring board through a connector, provided on the printed wiring board being caught in the cutouts of a conductive member so that the cable alternates between the top and the bottom thereof, the conductive member being provided on a side end part of the printed wiring board with the cutouts being formed in series at equal intervals on the conductive member (see, for instance, Patent Document 2).

-   -   [Patent Document 1] Japanese Patent No. 3483132     -   [Patent Document 2] Japanese Laid-Open Patent Application No.         2000-124695

DISCLOSURE OF THE INVENTION

Problems To Be Solved By the Invention

However, these prior-art techniques are for canceling a magnetic field in an interconnection member connected to a printed wiring board, but are not for canceling a magnetic field in the interconnection pattern of the printed wiring board.

Accordingly, the present invention has an object of providing a printed wiring board capable of canceling a magnetic field in the interconnection pattern of the printed wiring board.

Means For Solving the Problems

A printed wiring board according to the present invention includes a first interconnection pattern and a second interconnection pattern 180° different from each other in the direction in which current flows, where the first interconnection pattern and the second interconnection pattern are disposed closely in positions such that magnetic fields created thereby cancel each other.

A first mode of the printed wiring board of the present invention has the first interconnection pattern and the second interconnection pattern formed on the same plane surface.

In the first mode of the present invention, the first interconnection pattern and the second interconnection pattern may be formed by bending back a single interconnection line.

Further, the first interconnection pattern and the second interconnection pattern may function as resistors.

Further, the first interconnection pattern and the second interconnection pattern may be sandwiched between insulating materials so that there may be no metal plating provided on the first interconnection pattern and the second interconnection pattern.

In SCOPE OF PATENT CLAIMS of the present application and in this specification, the insulating materials include an insulating substrate.

A second mode of the printed wiring board of the present invention has two or more interconnection pattern layers, where the first interconnection pattern and the second interconnection pattern are formed in their respective different interconnection pattern layers.

In the second mode of the present invention, the first interconnection pattern and the second interconnection pattern may be formed by bending back a single interconnection line via a through hole.

Further, the first interconnection pattern and the second interconnection pattern may function as resistors.

Further, the first interconnection pattern and the second interconnection pattern may be sandwiched between insulating materials so that there may be no metal plating provided on the first interconnection pattern and the second interconnection pattern.

Further, the first interconnection pattern and the second interconnection pattern may be formed meanderingly.

EFFECTS OF THE INVENTION

In a printed wiring board of the present invention, a first interconnection pattern and a second interconnection pattern 180° different from each other in the direction in which current flows are provided, and the first interconnection pattern and the second interconnection pattern are disposed closely in positions such that magnetic fields created thereby cancel each other. Accordingly, it is possible to cancel magnetic fields in the first interconnection pattern and the second interconnection pattern.

In the first mode of the printed wiring board of the present invention, the first interconnection pattern and the second interconnection pattern are formed on the same plane surface. Accordingly, it is possible to cancel magnetic fields in the first interconnection pattern and the second interconnection pattern formed in the same interconnection pattern layer.

In the first mode of the present invention, the first interconnection pattern and the second interconnection pattern may be formed by bending back a single interconnection line. This makes it possible to cancel magnetic fields with efficiency since the same current flows through the first interconnection pattern and the second interconnection pattern.

Further, the first interconnection pattern and the second interconnection pattern may function as resistors. This makes it possible to form resistors without mounting resistor components on the printed wiring board.

Further, the first interconnection pattern and the second interconnection pattern may be sandwiched between insulating materials so that there may be no metal plating provided on the first interconnection pattern and the second interconnection pattern. This makes it possible to stabilize the film thickness of the first interconnection pattern and the second interconnection pattern. In particular, this makes it possible to stabilize resistance when the first interconnection pattern and the second interconnection pattern function as resistors.

In the second mode of the printed wiring board of the present invention, two or more interconnection pattern layers are provided, and the first interconnection pattern and the second interconnection pattern are formed in their respective different interconnection pattern layers. Accordingly, it is possible to cancel magnetic fields in the first interconnection pattern and the second interconnection pattern between the different interconnection pattern layers. Further, the first interconnection pattern and the second interconnection pattern can be disposed so as to be superposed in the stacking direction of the interconnection pattern layers. Accordingly, even in the case of increasing the line width of the first interconnection pattern and the second interconnection pattern, it is possible to cancel magnetic fields in the first interconnection pattern and the second interconnection pattern with efficiency.

In the second mode of the present invention, the first interconnection pattern and the second interconnection pattern may be formed by bending back a single interconnection line via a through hole. This makes it possible to cancel magnetic fields with efficiency since the same current flows through the first interconnection pattern and the second interconnection pattern.

Further, the first interconnection pattern and the second interconnection pattern may function as resistors. This makes it possible to form resistors without mounting resistor components on the printed wiring board.

Further, the first interconnection pattern and the second interconnection pattern may be sandwiched between insulating materials so that there may be no metal plating provided on the first interconnection pattern and the second interconnection pattern. This makes it possible to stabilize the film thickness of the first interconnection pattern and the second interconnection pattern. In particular, this makes it possible to stabilize resistance when the first interconnection pattern and the second interconnection pattern function as resistors.

Further, with respect to semiconductor components, the first interconnection pattern and the second interconnection pattern may be formed meanderingly. This makes it possible to increase the resistance of the first interconnection pattern and the second interconnection pattern. Even when the first interconnection pattern and the second interconnection pattern are formed meanderingly, it is possible to cancel magnetic fields in the first interconnection pattern and the second interconnection pattern since the first interconnection pattern and the second interconnection pattern can be disposed so as to be superposed in the stacking direction of the interconnection pattern layers.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is diagrams showing an embodiment of the second mode, where (A) is a plan view, (B) is a plan view showing the interconnection pattern layer of a bottom surface viewed from the upper surface side, and (C) is a cross-sectional view at the A-A position of (A).

FIG. 2 is diagrams showing another from the upper surface side, and (E) is a cross-sectional view at the D-D position of (A). embodiment of the second mode, where (A) is an upper surface view, (B) is a plan view showing the interconnection pattern layer of a bottom surface viewed from the upper surface side, and (C) is a cross-sectional view at the B-B position of (A).

FIG. 3 is diagrams showing yet another embodiment of the second mode, where (A) is a plan view showing a first-layer interconnection pattern layer, (B) is a plan view showing a second-layer interconnection pattern layer viewed from the upper surface side, (C) is a plan view showing a third-layer interconnection pattern layer viewed from the upper surface side, (D) is a plan view showing a fourth-layer interconnection pattern layer viewed from the upper surface side, and (E) is a cross-sectional view at the C-C position of (A).

FIG. 4 is diagrams showing still another embodiment of the second mode, where (A) is a plan view showing a first-layer interconnection pattern layer, (B) is a plan view showing a second-layer interconnection pattern layer viewed from the upper surface side, (C) is a plan view showing a third-layer interconnection pattern layer viewed from the upper surface side, (D) is a plan view showing a fourth-layer interconnection pattern layer viewed

FIG. 5 is a plan view showing an embodiment of the first mode.

FIG. 6 is diagrams showing another embodiment of the first mode, where (A) is a plan view showing a first-layer interconnection pattern layer, (B) is a plan view showing a second-layer interconnection pattern layer viewed from the upper surface side, (C) is a plan view showing a third-layer interconnection pattern layer viewed from the upper surface side, and (D) is a cross-sectional view at the E-E position of (A).

BEST MODE FOR CARRYING OUT THE INVENTION

FIG. 1 is diagrams showing an embodiment of the second mode. (A) is a plan view, (B) is a plan view showing the interconnection pattern layer of a bottom surface viewed from the upper surface side, and (C) is a cross-sectional view at the A-A position of (A).

For instance, on a surface 1 a of an insulating substrate 1 of epoxy resin of approximately 0.2 mm (millimeters) in film thickness, a first interconnection pattern 3 a, an electrode 3 b, and an electrode 3 c of copper of approximately 0.035 mm in film thickness are formed. The first interconnection pattern 3 a and the electrode 3 b are formed in succession. The first interconnection pattern 3 a is formed meanderingly.

For instance, a second interconnection pattern 5 a and an end part 5 b of copper of approximately 0.035 mm in film thickness are formed on a bottom surface 1 b of the insulating substrate 1 so as to be superposed on the shape of a meandering part of the first interconnection pattern 3 a and an end part 3 d on the opposite side from the electrode 3 b when viewed from the upper surface side. The end part 5 b is electrically connected to the end part 3 d of the first interconnection pattern 3 a via through holes 7 a. Another end part 5 c of the second interconnection pattern 5 a is disposed in a region corresponding to the electrode 3 c on the surface 1 a of the insulating substrate 1, and is electrically connected to the electrode 3 c via through holes 7 b. The distance between the first interconnection pattern 3 a and the second interconnection pattern 5 a is equivalent to the film thickness of the insulating substrate 1, which is 0.2 mm herein.

For instance, when current flows from the electrode 3 b to the electrode 3 c via the first interconnection pattern 3 a, the through holes 7 a, the second interconnection pattern 5 a, and the through holes 7 b, it is possible to cancel magnetic fields in the first interconnection pattern 3 a and the second interconnection pattern 5 a since the first interconnection pattern 3 a and the second interconnection pattern 5 a are 180° different from each other in the direction in which the current flows, and the first interconnection pattern 3 a and the second interconnection pattern 5 a are disposed closely in positions such that the magnetic fields created by both interconnection patterns 3 a and 5 a cancel each other.

Further, the first interconnection pattern 3 a and the second interconnection pattern 5 a form a single interconnection line via the through holes 7 a, so that the same current flows through the first interconnection pattern 3 a and the second interconnection pattern 5 a. Accordingly, it is possible to cancel magnetic fields with efficiency.

FIG. 2 is diagrams showing another embodiment of the second mode. (A) is an upper surface view, (B) is a plan view showing the interconnection pattern layer of a bottom surface viewed from the upper surface side, and (C) is a cross-sectional view at the B-B position of (A). The same parts as those of FIG. 1 are assigned the same numerals, and a description thereof is omitted.

In the embodiment shown in FIG. 1, the first interconnection pattern 3 a and the second interconnection pattern 5 a are formed meanderingly. Alternatively, for instance, a first interconnection pattern 3 e and a second interconnection pattern 5 d may be rectilinear as in this embodiment. The first interconnection pattern 3 e and the second interconnection pattern 5 d are formed so that their rectilinear parts are superposed when viewed from the upper surface side.

Also in this embodiment, for instance, when current flows from the electrode 3 b to the electrode 3 c via the first interconnection pattern 3 e, the through holes 7 a, the second interconnection pattern 5 d, and the through holes 7 b, it is possible to cancel magnetic fields in the first interconnection pattern 3 e and the second interconnection pattern 5 d since the first interconnection pattern 3 e and the second interconnection pattern 5 d are 180° different from each other in the direction in which the current flows, and the first interconnection pattern 3 e and the second interconnection pattern 5 d are disposed closely in positions such that the magnetic fields created by both interconnection patterns 3 e and 5 d cancel each other.

Further, the first interconnection pattern 3 e and the second interconnection pattern 5 d form a single interconnection line via the through holes 7 a, so that the same current flows through the first interconnection pattern 3 e and the second interconnection pattern 5 d. Accordingly, it is possible to cancel magnetic fields with efficiency.

FIG. 3 is diagrams showing yet another embodiment of the second mode. (A) is a plan view showing a first-layer interconnection pattern layer, (B) is a plan view showing a second-layer interconnection pattern layer viewed from the upper surface side, (C) is a plan view showing a third-layer interconnection pattern layer viewed from the upper surface side, (D) is a plan view showing a fourth-layer interconnection pattern layer viewed from the upper surface side, and (E) is a cross-sectional view at the C-C position of (A).

For instance, a first interconnection pattern 11 a of copper of approximately 0.018 mm in film thickness is formed on a surface 9 a of an insulating substrate 9 of epoxy resin of approximately 0.2 mm in film thickness. The first interconnection pattern 11 a, which is formed meanderingly, has end parts 11 b and 11 c.

For instance, an insulating material 13 of epoxy resin of approximately 0.1 mm in film thickness is applied on the surface 9 a of the insulating substrate 9 through an adhesive agent (of which graphical representation is omitted).

For instance, an electrode 15 of copper of approximately 0.035 mm in film thickness corresponding to the end part 11 c of the first interconnection pattern 11 a is formed on a surface 13 a of the insulating material 13.

For instance, a second interconnection pattern 17 a and an end part 17 b of copper of approximately 0.018 mm in film thickness are formed on a bottom surface 9 b of the insulating substrate 9 so as to be superposed on the shape of a meandering part of the first interconnection pattern 11 a and the end part 11 b when viewed from the upper surface side. Another end part 17 c of the second interconnection pattern 17 a is formed in a region different from the end part 11 c when viewed from the upper surface side.

For instance, an insulating material 19 of epoxy resin of approximately 0.1 mm in film thickness is applied on the bottom surface 9 b of the insulating substrate 9 through an adhesive agent (of which graphical representation is omitted).

For instance, an electrode 21 of copper of approximately 0.035 mm in film thickness corresponding to the end part 17 c of the second interconnection pattern 17 a is formed on a surface 19 a (a surface on the opposite side from the insulating substrate 9) of the insulating material 19.

The end part 11 c of the first interconnection pattern 11 a and the electrode 15 are electrically connected via through holes 23 a. The end part 11 b of the first interconnection pattern 11 a and the end part 17 b of the second interconnection pattern 17 a are electrically connected via through holes 23 b. The end part 17 c of the second interconnection pattern 17 a and the electrode 21 are electrically connected via through holes 23 c. The through holes 23 a, 23 b, and 23 c are formed through the insulating material 13, the insulating substrate 9, and the insulating material 19.

The through holes 23 a, 23 b, and 23 c are formed by copper plating. The electrodes 15 and 21 are also plated with copper at the time of forming the through holes 23 a, 23 b, and 23 c. The first interconnection pattern 11 a and the second interconnection pattern 17 a are covered with the insulating materials 13 and 19 at the time of copper plating. Accordingly, no plating is provided on the first interconnection pattern 11 a and the second interconnection pattern 17 a.

For instance, when current flows from the electrode 15 to the electrode 21 via the through holes 23 a, the first interconnection pattern 11 a, the through holes 23 b, the second interconnection pattern 17 a, and the through holes 23 c, it is possible to cancel magnetic fields in the first interconnection pattern 11 a and the second interconnection pattern 17 a since the first interconnection pattern 11 a and the second interconnection pattern 17 a are 180° different from each other in the direction in which the current flows, and the first interconnection pattern 11 a and the second interconnection pattern 17 a are disposed closely in positions such that the magnetic fields created by both interconnection patterns 11 a and 17 a cancel each other.

Further, the first interconnection pattern 11 a and the second interconnection pattern 17 a form a single interconnection line via the through holes 23 b, so that the same current flows through the first interconnection pattern 11 a and the second interconnection pattern 17 a. Accordingly, it is possible to cancel magnetic fields with efficiency.

FIG. 4 is diagrams showing still another embodiment of the second mode. (A) is a plan view showing a first-layer interconnection pattern layer, (B) is a plan view showing a second-layer interconnection pattern layer viewed from the upper surface side, (C) is a plan view showing a third-layer interconnection pattern layer viewed from the upper surface side, (D) is a plan view showing a fourth-layer interconnection pattern layer viewed from the upper surface side, and (E) is a cross-sectional view at the D-D position of (A). The same parts as those of FIG. 3 are assigned the same numerals, and a description thereof is omitted.

In the embodiment shown in FIG. 3, the first interconnection pattern 3 a and the second interconnection pattern 5 a are formed meanderingly. Alternatively, for instance, a first interconnection pattern 11 d and a second interconnection pattern 17 d may be rectilinear as shown in FIG. 4. The first interconnection pattern 11 d and the second interconnection pattern 17 d are formed so that their rectilinear parts are superposed when viewed from the upper surface side.

Also in this embodiment, for instance, when current flows from the electrode 15 to the electrode 21 via the through holes 23 a, the first interconnection pattern 11 a, the through holes 23 b, the second interconnection pattern 17 a, and the through holes 23 c, it is possible to cancel magnetic fields in the first interconnection pattern 11 d and the second interconnection pattern 17 d as in the embodiment shown in FIG. 3.

Further, the first interconnection pattern 11 d and the second interconnection pattern 17 d form a single interconnection line via the through holes 23 b, so that the same current flows through the first interconnection pattern 11 d and the second interconnection pattern 17 d. Accordingly, it is possible to cancel magnetic fields with efficiency.

In both embodiments described with reference to FIGS. 3 and 4, the first interconnection pattern and the second interconnection pattern are formed by middle-layer interconnection pattern layers (a second layer and a third layer), exclusive of the uppermost layer (a first layer) and the lowermost layer (a fourth layer), in a printed wiring board having a four-layer structure. However, the present invention is not limited to this, and for instance, the first interconnection pattern and the second interconnection pattern may be formed in the first layer and the second layer.

Further, the first interconnection pattern and the second interconnection pattern do not always have to be formed in two vertically adjacent layers. For instance, the first interconnection pattern may be formed in the first layer, and the second interconnection pattern may be formed in the third layer.

Further, in the embodiments described with reference to FIGS. 1 through 4, the first interconnection pattern and the second interconnection pattern have a meandering shape or are rectilinear. However, the second mode of the present invention is not limited to this. The first interconnection pattern and the second interconnection pattern may be curved lines.

FIG. 5 is a plan view showing an embodiment of the first mode.

For instance, a first interconnection pattern 27 a, a second interconnection pattern 27 b, a bent-back part 27 c, an electrode 27 d, and an electrode 27 e of copper of approximately 0.035 mm in film thickness are formed on a surface of an insulating substrate 25 of epoxy resin of approximately 0.2 mm in film thickness.

The first interconnection pattern 27 a and the second interconnection pattern 27 b are disposed closely in parallel. An end part of the first interconnection pattern 27 a is connected to the electrode 27 d, and the other end part thereof is connected to the bent-back part 27 c. An end part of the bent-back part 27 c on the opposite side from the first interconnection pattern 27 a is connected to an end part of the second interconnection pattern 27 b. The other end part of the second interconnection pattern 27 b is connected to the electrode 27 e.

The line width of the first interconnection pattern 27 a and the second interconnection pattern 27 b is, for instance, 0.8 mm, and the interval between the first interconnection pattern 27 a and the second interconnection pattern 27 b is, for instance, 0.2 mm.

For instance, when current flows from the electrode 27 d to the electrode 27 e via the first interconnection pattern 27 a, the bent-back part 27 c, and the second interconnection pattern 27 b, it is possible to cancel magnetic fields in the first interconnection pattern 27 a and the second interconnection pattern 27 b since the first interconnection pattern 27 a and the second interconnection pattern 27 b are 180° different from each other in the direction in which the current flows, and the first interconnection pattern 27 a and the second interconnection pattern 27 b are disposed closely in positions such that the magnetic fields created by both interconnection patterns 27 a and 27 b cancel each other.

Further, the first interconnection pattern 27 a and the second interconnection pattern 27 b form a single interconnection line through the bent-back part 27 c, so that the same current flows through the first interconnection pattern 27 a and the second interconnection pattern 27 b. Accordingly, it is possible to cancel magnetic fields with efficiency.

FIG. 6 is diagrams showing another embodiment of the first mode. (A) is a plan view showing a first-layer interconnection pattern layer, (B) is a plan view showing a second-layer interconnection pattern layer viewed from the upper surface side, (C) is a plan view showing a third-layer interconnection pattern layer viewed from the upper surface side, and (D) is a cross-sectional view at the E-E position of (A).

For instance, a first interconnection pattern 31 a, a second interconnection pattern 31 b, and a bent-back part 31 c of copper of approximately 0.018 mm in film thickness are formed on a surface 29 a of an insulating substrate 29 of epoxy resin of approximately 0.2 mm in film thickness.

The first interconnection pattern 31 a and the second interconnection pattern 31 b are disposed closely in parallel. An end part of the first interconnection pattern 31 a on the opposite side from an end part 31 d thereof is connected to the bent-back part 31 c. An end part of the bent-back part 31 c on the opposite side from the first interconnection pattern 31 a is connected to an end part of the second interconnection pattern 31 b. The other end part of the second interconnection pattern 31 b is indicated by numeral 31 e.

The line width of the first interconnection pattern 31 a and the second interconnection pattern 31 b is, for instance, 0.8 mm, and the interval between the first interconnection pattern 31 a and the second interconnection pattern 31 b is, for instance, 0.2 mm.

For instance, an insulating material 33 of epoxy resin of approximately 0.1 mm in film thickness is applied on the surface 29 a of the insulating substrate 29 through an adhesive agent (of which graphical representation is omitted).

For instance, an electrode 35 of copper of approximately 0.035 mm in film thickness corresponding to the end part 31 c of the first interconnection pattern 31 a is formed on a surface 33 a of the insulating material 33.

For instance, an electrode 37 of copper of approximately 0.035 mm in film thickness corresponding to the end part 31 e of the second interconnection pattern 31 b is formed on a bottom surface 29 b of the insulating substrate 29.

The end part 31 c of the first interconnection pattern 31 a and the electrode 35 are electrically connected via through holes 39 a. The end part 31 e of the second interconnection pattern 31 b and the electrode 37 are electrically connected via through holes 39 b. The through holes 39 a and 39 b are formed through the insulating material 33 and the insulating substrate 29.

The through holes 39 a and 39 b are formed by copper plating. The electrodes 35 and 37 are plated with copper at the time of forming the through holes 39 a and 39 b. The first interconnection pattern 31 a and the second interconnection pattern 31 b are covered with the insulating substrate 29 and the insulating material 33 at the time of copper plating. Accordingly, no plating is provided on the first interconnection pattern 31 a and the second interconnection pattern 31 b.

For instance, when current flows from the electrode 35 to the electrode 37 via the through holes 39 a, the first interconnection pattern 31 a, the bent-back part 31 c, the second interconnection pattern 31 b, and the through holes 39 b, it is possible to cancel magnetic fields in the first interconnection pattern 31 a and the second interconnection pattern 31 b since the first interconnection pattern 31 a and the second interconnection pattern 31 b are 180° different from each other in the direction in which the current flows, and the first interconnection pattern 31 a and the second interconnection pattern 31 b are disposed closely in positions such that the magnetic fields created by both interconnection patterns 31 a and 31 b cancel each other.

Further, the first interconnection pattern 31 a and the second interconnection pattern 31 b form a single interconnection line via the bent-back part 31 c, so that the same current flows through the first interconnection pattern 31 a and the second interconnection pattern 31 b. Accordingly, it is possible to cancel magnetic fields with efficiency.

In both embodiments described with reference to FIGS. 5 and 6, the first interconnection pattern and the second interconnection pattern are rectilinear. However, the first mode of the present invention is not limited to this. The first interconnection pattern and the second interconnection pattern may be bent or curved lines.

The embodiments of the first mode and the second mode have been described with reference to FIGS. 1 through 6. The first interconnection pattern and the second interconnection pattern forming the present invention may be used as resistors. In particular, as in the embodiments shown in FIGS. 3, 4, and 6, in a printed circuit board having multiple interconnection pattern layers, the first interconnection pattern and the second interconnection pattern may be sandwiched between insulating materials so that there may be no metal plating provided on the first interconnection pattern and the second interconnection pattern. This makes it possible to stabilize the film thickness of the first interconnection pattern and the second interconnection pattern, thus making it possible to stabilize resistance.

A description is given above of embodiments of the present invention, but the present invention is not limited to these. Shapes, materials, and dispositions are examples, and variations may be made within the scope of the present invention recited in SCOPE OF PATENT CLAIMS.

DESCRIPTION OF THE REFERENCE NUMERALS

-   1, 9, 25, 29 Insulating substrates -   1 a, 9 a, 29 a Surfaces of the insulating substrates -   1 b, 9 b, 29 b Bottom surfaces of the insulating substrates -   3 a, 5 e, 11 a, 11 d, 27 a, 31 a First interconnection patterns -   3 b, 3 c, 15, 21, 27 d, 27 e, 31 d, 31 e, 35, 37 Electrodes -   3 d, 11 b, 11 c, 31 b End parts of the first interconnection     patterns -   5 a, 5 e, 17 a, 17 d, 27 b, 31 b Second interconnection patterns -   5 b, 5 c, 17 b, 17 c, 31 e End parts of the second interconnection     patterns -   7 a, 7 b, 23 a, 23 b, 23 c, 39 a, 39 b Through holes -   13, 19, 33 Insulating materials -   13 a, 19 a, 33 a Surfaces of the insulating materials -   27 c, 31 c Bent-back parts 

1. A printed wiring board, comprising: a first interconnection pattern and a second interconnection pattern 180° different from each other in a direction in which current flows, wherein the first interconnection pattern and the second interconnection pattern are disposed closely in positions such that magnetic fields created thereby cancel each other.
 2. The printed wiring board as claimed in claim 1, wherein the first interconnection pattern and the second interconnection pattern are formed on a same plane surface.
 3. The printed wiring board as claimed in claim 2, wherein the first interconnection pattern and the second interconnection pattern are formed by bending back a single interconnection line.
 4. The printed wiring board as claimed in claim 2 or 3, wherein the first interconnection pattern and the second interconnection pattern function as resistors.
 5. The printed wiring board as claimed in claim 2, 3, or 4, wherein the first interconnection pattern and the second interconnection pattern are sandwiched between insulating materials so that no metal plating is provided on the first interconnection pattern and the second interconnection pattern.
 6. The printed wiring board as claimed in claim 1, comprising two or more interconnection pattern layers, wherein the first interconnection pattern and the second interconnection pattern are formed in respective different ones of the interconnection pattern layers.
 7. The printed wiring board as claimed in claim 6, wherein the first interconnection pattern and the second interconnection pattern are formed by bending back a single interconnection line via a through hole.
 8. The printed wiring board as claimed in claim 6 or 7, wherein the first interconnection line and the second interconnection line function as resistors.
 9. The printed wiring board as claimed in claim 6, 7, or 8, wherein the first interconnection pattern and the second interconnection pattern are sandwiched between insulating materials so that no metal plating is provided on the first interconnection pattern and the second interconnection pattern.
 10. The printed wiring board as claimed in any of claims 6 to 9, wherein the first interconnection pattern and the second interconnection pattern are formed meanderingly. 